Flow boiling heat transfer of HFE-7000 in nanowire-coated microchannels

Flow boiling heat transfer of HFE-7000 in nanowire-coated microchannels

•Flow boiling of dielectric fluid (HFE-7000) was studied in nanowired microchannels.•Annual flow was generated by capillary effects in low mass flux and heat flux.•Critical heat flux was limited to 120 W/cm2 in high mass fluxes.•Optimal working conditions were found for enhanced flow boiling using n...

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Bibliographic Details
Published in:Applied thermal engineering Vol. 93; pp. 260 - 268
Main Authors: Yang, Fanghao, Li, Wenming, Dai, Xianming, Li, Chen
Format: Journal Article
Language:English
Published: Elsevier Ltd 25-01-2016
Subjects:
Boiling
Dielectric fluid
Electronics cooling
Evaporation
Flow boiling
Fluids
Heat transfer
Microchannels
Nanostructure
Nanowire
Nuclear power generation
Thin films
Dielectric fluid
Nanowire
Flow boiling
Electronics cooling
Microchannels
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Summary:•Flow boiling of dielectric fluid (HFE-7000) was studied in nanowired microchannels.•Annual flow was generated by capillary effects in low mass flux and heat flux.•Critical heat flux was limited to 120 W/cm2 in high mass fluxes.•Optimal working conditions were found for enhanced flow boiling using nanowires.•Flow pattern and interfacial stress were analyzed to understand flow boiling results. Flow boiling of dielectric fluids in microchannels is among the most promising embedded cooling solutions for high power electronics. However, it is normally limited by their poor thermal conductivity and small latent heat. To promote thin film evaporation and nucleate boiling, the side and bottom walls of five parallel microchannels were structured with nanowires in a silicon chip. A 10-mm-long thin-film heater was built-in to simulate heat source. Wall temperatures were measured from adiabatic condition to critical heat flux (CHF) conditions. Compared to the plain-wall microchannels with identical channel dimensions, heat transfer coefficient of HFE 7000 can be substantially enhanced up to 344% at the mass flux ranging from 1018 kg/m2⋅s to 2206 kg/m2⋅s as promoted evaporation and nucleate boiling. Moreover, pumping power was reduced up to 40% owing to the capillarity-enhanced phase separation. CHF was achieved from 92 to 120 W/cm2 and enhanced up to 14.9% at moderate mass flux of 1018 kg/m2⋅s as a result of annular liquid supply. However, interestingly, this trend is non-monotonic and CHF is reduced at higher mass fluxes. This experimental study is trying to explore an optimal range of working conditions using nanostructures in flow boiling on highly-wetting dielectric fluids.
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ISSN:1359-4311
DOI:10.1016/j.applthermaleng.2015.09.097